Cutting apparatus

What is claimed is: 1. A cutting apparatus comprising: a cutter to cut a work material; a holder to support the cutter so as to enable the cutter to approach toward and move away from the work material; a carriage to support the holder and being movable relatively to the work material; a first motor coupled to the carriage to cause the carriage to move relatively to the work material; a second motor coupled to the holder to impart a force to the holder at least toward the work material; and a controller configured or programmed to control the first motor and the second motor; wherein the second motor is capable of changing the force to be imparted to the holder according to a supply signal supplied to the second motor; and the controller is configured or programmed to include: a load detector to detect a load of the first motor; a storage to store a first relationship that is a predetermined relationship between the load of the first motor and the supply signal to the second motor; and a cutting pressure controller configured or programmed to control a cutting pressure applied from the cutter to the work material by supplying the supply signal to the second motor based on the load of the first motor detected by the load detector and the first relationship stored in the storage. 2. The cutting apparatus according to claim 1 , wherein the supply signal of the first relationship is set so that the work material receives a first cutting pressure from the cutter when the load of the first motor is at a first load, and so that the work material receives a second cutting pressure higher than the first pressure when the load of the first motor is at a second load greater than the first load. 3. The cutting apparatus according to claim 1 , wherein the supply signal of the first relationship is set so that the cutting pressure applied from the cutter to the work material is constant when the load of the first motor is equal to or less than a first threshold value, and so that the cutting pressure increases as the load of the first motor increases when the load of the first motor is greater than the first threshold value. 4. The cutting apparatus according to claim 1 , wherein: the first motor includes a rotary shaft; and the cutting apparatus further comprises: an encoder synchronized with rotation of the rotary shaft of the first motor to output a pulse signal at each of at least one predetermined rotation angle; and an encoder counter to count the pulse signal from the encoder; wherein the load detector calculates a cutting speed of the carriage relative to the work material from the pulse signal counted by the encoder counter and calculates, as the load of the first motor, a speed deviation amount that is a difference between the cutting speed of the carriage and a target cutting speed of the carriage. 5. The cutting apparatus according to claim 4 , wherein: the controller is configured or programmed to move the carriage relatively to the work material while accelerating the carriage at an initial stage of cutting; and the load detector calculates, as the load of the first motor, the speed deviation amount during the accelerating. 6. The cutting apparatus according to claim 1 , wherein the first motor includes a rotary shaft; and the cutting apparatus further comprises: an encoder synchronized with rotation of the rotary shaft of the first motor to output a pulse signal at each of at least one predetermined rotation angle; and an encoder counter to count the pulse signal from the encoder; wherein the load detector calculates a position of the carriage relative to the work material from the pulse signal counted by the encoder counter and calculates, as the load of the first motor, a position deviation amount that is a difference between the position of the carriage and a target position of the carriage. 7. The cutting apparatus according to claim 6 , wherein: the controller is configured or programmed to move the carriage relatively to the work material while accelerating the carriage at an initial stage of cutting; and the load detector calculates, as the load of the first motor, the position deviation amount during the accelerating. 8. The cutting apparatus according to claim 1 , further comprising: a carriage motor to move the carriage in a first direction; a grid roller to transfer the work material in a second direction that is perpendicular or substantially perpendicular to the first direction; and a feed motor to rotate the grid roller; wherein the first motor is the carriage motor or the feed motor. 9. A cutting apparatus comprising: a cutter to cut a work material; a holder to support the cutter so as to enable the cutter to approach toward and move away from the work material; a carriage to support the holder and being movable relatively to the work material; a first motor coupled to the carriage to cause the carriage to move relatively to the work material; a second motor coupled to the holder to impart a force to the holder at least in a direction approaching toward the work material; and a controller configured or programmed control the first motor and the second motor; wherein the second motor is capable of changing the force to be imparted to the holder according to a supply signal supplied to the second motor; and the controller is configured or programmed to include: a load detector to detect a load of the first motor; a storage to store a second relationship that is a predetermined relationship between the load of the first motor and the supply signal to the first motor; and a cutting speed controller configured or programmed to control a cutting speed for the work material by supplying the supply signal to the first motor based on the load of the first motor detected by the load detector and the second relationship stored in the storage. 10. The cutting apparatus according to claim 9 , wherein the supply signal of the second relationship is set so that the cutting speed for the work material becomes a first cutting speed when the load of the first motor is at a first load, and that the cutting speed for the work material becomes a second speed lower than the first speed when the load of the first motor is at a second load greater than the first load. 11. The cutting apparatus according to claim 9 , wherein the supply signal of the second relationship is set so that the cutting speed for the work material is constant when the load of the first motor is equal to or less than a second threshold value, and so that the cutting speed reduces as the load of the first motor increases when the load of the first motor is greater than the second threshold value. 12. The cutting apparatus according to claim 9 , wherein: the first motor includes a rotary shaft; the cutting apparatus further comprises: an encoder synchronized with rotation of the rotary shaft of the first motor to output a pulse signal at each of at least one predetermined rotation angle; and an encoder counter to count the pulse signal from the encoder; wherein the load detector calculates a cutting speed of the carriage relative to the work material from the pulse signal counted by the encoder counter and calculates, as the load of the first motor, a speed deviation amount that is a difference between the cutting speed of the carriage and a target cutting speed of the carriage. 13. The cutting apparatus according to claim 12 , wherein the controller is configured or programmed to move the carriage relatively to the work material while accelerating the carriage at an initial stage of cutting; and the load detector calcu